JP6934285B2 - Wooden column beam joint structure - Google Patents

Description

The present invention relates to a wooden column-beam joint structure.

Wood braces formed from wood are known (see, for example, Patent Documents 1 and 2).

Japanese Unexamined Patent Publication No. 2015-140616 Japanese Unexamined Patent Publication No. 10-237950

By the way, there are wooden pillars made of wood. It is conceivable to join horizontal members such as steel-framed or reinforced concrete beams to the wooden columns, but in this case, it is desirable to transmit a tensile force between the wooden columns and the horizontal members.

In consideration of the above facts, an object of the present invention is to join a wooden column and a horizontal member so that a tensile force can be transmitted.

The wooden column-beam joining structure according to the first aspect is a wooden column, a pair of beam-column joint members arranged above and below the wooden column, and horizontal members to be joined to each other, and the wooden column in the timber axial direction. A linear member for connecting the pair of column-beam joint members in a state of penetrating the column and the beam.

According to the wooden column-beam joint structure according to the first aspect , a pair of column-beam joint members are arranged above and below the wooden column. Horizontal members are joined to the pair of beam-column joint members. Further, the pair of beam-column joint members are connected by linear members penetrating the wooden columns in the timber axial direction.

As a result, for example, in the event of an earthquake, a tensile force is transmitted from the upper and lower horizontal members to the linear member via the pair of beam-column joint members. When the linear member resists this tensile force, the tensile force is transmitted between the wooden column and the horizontal member.

As described above, in the present invention, the wooden column and the horizontal member can be joined so that the tensile force can be transmitted.

The wooden column-beam joint structure according to the second aspect is the wooden column-beam joint structure according to the first aspect, in which the column-beam joint member is in contact with the end face of the wooden column so as to be separable, and the linear member. The end portion of the linear member is provided with a locking member that is locked to the connecting base.

According to the wooden column-beam joint structure according to the second aspect , the column-beam joint member has a connecting base. The connecting base is separably contacted with the end face of the wooden pillar. Therefore, for example, when a tensile force is transmitted from the horizontal member to the pair of beam-column joint members during an earthquake, the connecting base is separated from the end face of the wooden column. As a result, the transmission of tensile force from the pair of beam-column joint members to the wooden columns is suppressed. Therefore, damage to the end of the wooden pillar is suppressed.

On the other hand, the end portion of the linear member is penetrated through the connecting base. A locking member is provided at the end of the linear member. By locking this locking member to the connecting base, the end portion of the linear member is connected to the connecting base. As a result, for example, when a tensile force is transmitted from the horizontal member to the pair of beam-column joint members during an earthquake, the tensile force is transmitted from the connecting base of the pair of beam-column joint members to the linear member via the locking member. Is transmitted.

As described above, in the present invention, the tensile force can be transmitted to the linear member while suppressing the breakage of the end portion of the wooden pillar. Therefore, the seismic performance of the wooden pillars is improved.

Here, the wooden pillar may be compressed in the timber axial direction due to a vertical load or the like. When the linear member follows the compressive deformation of the wooden pillar, the linear member may be curved inside the wooden pillar, and the wooden pillar may be damaged from the inside.

On the other hand, in the present invention, when the wooden column is compressed and deformed in the direction of the material axis, the locking member is separated from the connecting base, and the locked state between the connecting base and the locking member is released. Therefore, the linear member does not follow the compressive deformation of the wooden column. Therefore, since the bending of the linear member is suppressed, the breakage of the wooden pillar is suppressed.

The wooden column-beam joint structure according to the third aspect is the wooden column-beam joint structure according to the second aspect. Has.

According to the wooden column-beam joint structure according to the third aspect , the column-beam joint member has a moving space that allows the locking member to move to the opposite side to the wooden column. As a result, when the wooden pillar is compressed and deformed in the direction of the lumber axis, the locking member moves to the side opposite to the wooden pillar, and the locked state between the connecting base and the locking member is released. Therefore, the linear member does not follow the compressive deformation of the wooden column. Therefore, since the bending of the linear member is suppressed, the breakage of the wooden pillar is suppressed.

As described above, according to the wooden column-beam joining structure according to the present invention, the wooden column and the horizontal member can be joined so that the tensile force can be transmitted.

It is an elevation view which shows the frame to which the wooden column beam joint structure which concerns on one Embodiment is applied. (A) is a partially enlarged elevational view of FIG. 1, and (B) is a cross-sectional view taken along the line 2B-2B of FIG. 2 (A). FIG. 3 is an exploded elevation view showing a state in which the beam-column joint member shown in FIG. 2A and the upper and lower wooden columns are disassembled. It is an enlarged elevation view corresponding to FIG. 2A which shows the state which the tensile force acted from the beam to the column-beam joint member at the time of an earthquake. It is an enlarged elevation view corresponding to FIG. 2A which shows the state in which the wooden column above the beam-column joint member is compressed and the nut is separated downward from the upper connecting base of the beam-column joint member. It is an elevation view which shows the frame to which the modified example of the wooden column beam joint structure which concerns on one Embodiment is applied. It is sectional drawing corresponding to FIG. 2B which shows the modification of the column-beam joint member which concerns on one Embodiment.

Hereinafter, the wooden beam-column joint structure according to the embodiment will be described with reference to the drawings.

(Frame)
FIG. 1 shows a frame 12 to which the wooden beam-column joint structure 10 according to the present embodiment is applied. The frame 12 has a pair of wooden columns 14 and upper and lower beams 16 erected on the pair of wooden columns 14.

The wood pillar 14 is formed in a prismatic shape by a wood material such as laminated wood or solid wood. The wooden pillar 14 may be formed in a columnar shape.

On the other hand, the upper and lower beams 16 are steel beams formed of H-shaped steel. As shown in FIG. 2, each beam 16 has an upper and lower flange portion 16A and a web portion 16B connecting the upper and lower flange portions 16A. The upper and lower beams 16 and the pair of wooden columns 14 are joined via a beam-column joint member 40, which will be described later.

The beam 16 is not limited to the H-shaped steel, and may be formed of a steel frame such as an I-shaped steel, a C-shaped steel, or a box steel. The beam 16 is an example of a horizontal member.

(Shear wall)
A seismic wall 20 as a seismic member (seismic element) is provided on the structural surface of the frame 12. The earthquake-resistant wall 20 is arranged between the upper and lower beams 16 and is joined to the upper and lower beams 16, respectively. On the other hand, the earthquake-resistant wall 20 is arranged at a position away from the pair of wooden pillars 14, and is not joined to the pair of wooden pillars 14. That is, the edge of the earthquake-resistant wall 20 and the pair of wooden pillars 14 is cut off. Further, an opening 18 is formed between the earthquake-resistant wall 20 and the pair of wooden pillars 14. The opening 18 can be omitted.

The earthquake-resistant wall 20 is, for example, a steel earthquake-resistant wall. The earthquake-resistant wall 20 has a wall body 22 and an outer peripheral frame 26 provided on the outer peripheral portion of the wall body 22. The wall body 22 is formed of a steel plate or the like. The wall body 22 is reinforced by a plurality of vertical ribs 24A and horizontal ribs 24B.

The outer peripheral frame 26 is formed in a rectangular frame shape by a steel plate or the like, and is joined to the outer peripheral portion of the wall body 22 by welding or the like. Further, on the upper surface of the outer peripheral frame 26, a flange portion 28 projecting to the upper beam 16 is provided. The flange portion 28 is joined to a flange portion (not shown) protruding from the lower surface of the beam 16 toward the earthquake-resistant wall 20 by bolts and nuts (not shown).

Similarly, on the lower surface of the outer peripheral frame 26, a flange portion 30 projecting to the lower beam 16 is provided. The flange portion 30 is joined to a flange portion (not shown) protruding from the upper surface of the lower beam 16 toward the earthquake-resistant wall 20 by bolts and nuts (not shown).

The joining structure (mounting structure) of the earthquake-resistant wall 20 to the frame 12 can be changed as appropriate. For example, the earthquake-resistant wall 20 may be joined to the frame 12 by welding or the like. It is also possible to provide a wooden panel or the like on the surface of the seismic wall 20 to enhance the rigidity and design of the seismic wall 20.

(Wooden column-beam joint structure)
A pair of beam-column joint members 40 are arranged above and below the wooden columns 14. The pair of beam-column joint members 40 are connected by a linear member 50 that penetrates the wooden columns 14 in the timber axial direction. In other words, the linear member 50 connects a pair of column-beam joint members 40 in a state of penetrating the wooden column 14 in the material axis direction.

(Column and beam joint member)
One of the beam-column joint members 40 of the pair of beam-column joint members 40 is arranged above the wooden columns 14. The upper beam 16 is joined to the upper end of the wooden column 14 via the beam-column joint member 40. Further, the other beam-column joint member 40 is arranged below the wooden column 14. The lower beam 16 is joined to the lower end of the wooden column 14 via the beam-column joint member 40.

In this embodiment, wooden columns 14 are arranged above and below the beam-column joint member 40. In other words, the column-beam joint member 40 is arranged between the wooden columns 14 adjacent to each other in the vertical direction. Therefore, in the following, for convenience of explanation, the configuration of the upper part of the wooden column 14 refers to the wooden column 14 arranged under the column-beam joint member 40, and the configuration of the lower part of the wooden column 14 is the column-beam structure. It shall be referred to the wooden pillar 14 arranged on the upper side of the mouth member 40.

As shown in FIGS. 2A and 2B, the beam-column joint member 40 has a joint main body 42, a lower connection base 44L as a connection base, and an upper connection base 44U. ing. As shown in FIG. 2B, the joint main body 42 is formed by joining two steel plates in a cross shape in a plan view. The flat cross-sectional shape of the joint main body 42 has a cross shape.

As shown in FIGS. 2A and 3, lower connecting bases 44L and upper connecting bases 44U are provided above and below the joint body 42. The lower connecting base 44L and the upper connecting base 44U are formed of, for example, a steel plate or the like, and are joined to the upper end or the lower end of the joint main body 42 by welding or the like. Further, each of the lower connecting base 44L and the upper connecting base 44U is formed in a rectangular shape in a plan view according to the planographical cross-sectional shape of the wooden pillar 14.

The lower connecting base 44L is overlapped with the upper end surface 14U of the wooden pillar 14. The lower connecting base 44L is not joined to the wooden pillar 14, and can be separated from the upper end surface 14U of the wooden pillar 14. That is, the lower connecting base 44L is in contact with the upper end surface 14U of the wooden pillar 14 so as to be separable.

Further, a mounting hole 46 is formed in the lower connecting base 44L. The mounting hole 46 is a circular through hole that penetrates the lower connecting base 44L in the thickness direction. The upper end portion 50U of the linear member 50, which will be described later, is inserted into the mounting hole 46.

The upper connecting base 44U is overlapped with the lower end surface 14L of the wooden pillar 14. The upper connecting base 44U is not joined to the wooden pillar 14, and can be separated from the lower end surface 14L of the wooden pillar 14. That is, the upper connecting base 44U is in contact with the lower end surface 14L of the wooden pillar 14 so as to be separable.

Further, a mounting hole 48 is formed in the upper connecting base 44U. The mounting hole 48 is a circular through hole that penetrates the upper connecting base 44U in the thickness direction. The lower end portion 50L of the linear member 50, which will be described later, is inserted into the mounting hole 48.

The shape of the mounting holes 46 and 48 is not limited to a circular shape, and may be, for example, a rectangular shape. Further, in the lower connecting base 44L and the upper connecting base 44U, instead of the mounting holes 46 and 48, a groove or a notch through which the upper end portion 50U or the lower end portion 50L of the linear member 50 penetrates may be formed. ..

A plurality of moving spaces 49 are formed between the lower connecting base 44L and the upper connecting base 44U. The plurality of moving spaces 49 are divided into four by the joint main body 42. Nuts 52 and 54, which will be described later, are arranged in each moving space 49.

Here, the end portion of the beam 16 is joined to the column-beam joint member 40. Specifically, the upper and lower flange portions 16A of the beam 16 are joined to the upper connecting base 44U and the lower connecting base 44L of the beam-column joint member 40 by welding. Further, a web joint 43 is provided in the joint main body 42 of the column-beam joint member 40. The web joint 43 is joined (bolt-joined) by a bolt 56 and a nut (not shown) in a state of being overlapped with the web portion 16B of the beam 16.

The method of joining the beam 16 to the column-beam joint member 40 can be changed as appropriate. Therefore, the upper connecting base 44U and the lower connecting base 44L of the beam-column joint member 40 and the upper and lower flange portions 16A of the beam 16 may be bolted together, for example, via a splice plate or the like.

(Wooden pillar)
As shown in FIG. 2A, a plurality of (four in this embodiment) through holes 15 are formed in the wooden pillar 14. The plurality of through holes 15 are circular through holes that penetrate the wood pillar 14 in the material axis direction. A linear member 50 is penetrated through each through hole 15.

The shape of the through hole 15 can be changed as appropriate, and may be, for example, an elliptical shape or a rectangular shape. Further, the number and arrangement of the through holes 15 can be changed as appropriate.

(Linear member)
The linear member 50 is formed of, for example, a PC steel rod, a PC steel wire, a reinforcing bar, a steel plate, or the like. Further, the diameter of the linear member 50 is smaller than the diameter of the through hole 15 of the wooden pillar 14. The linear member 50 is slidably penetrated through the through hole 15 of the wooden pillar 14.

The upper end portion 50U of the linear member 50 extends upward from the upper end surface 14U of the wooden pillar 14. The upper end portion 50U of the linear member 50 penetrates the mounting hole 46 formed in the lower connecting base 44L of the beam-column joint member 40.

Further, a male screw portion is provided on the upper end portion 50U of the linear member 50. A nut 52 as a locking member is attached to the male screw portion. By tightening the nut 52 to the upper end portion 50U (male screw portion) of the linear member 50, the nut 52 is locked to the upper surface of the lower connecting base 44L.

Further, the upper end portion 50U and the nut 52 of the linear member 50 are arranged in the moving space 49 of the beam-column joint member 40. As a result, the upper end portion 50U and the nut 52 of the linear member 50 can be moved to the opposite side (upper side) of the lower wooden pillar 14 with respect to the lower connecting base 44L.

The lower end portion 50L of the linear member 50 extends downward from the lower end surface 14L of the wooden pillar 14. The lower end portion 50L of the linear member 50 penetrates the mounting hole 48 formed in the upper connecting base 44U.

Further, a male screw portion is provided at the lower end portion 50L of the linear member 50. A nut 54 as a locking member is attached to the male screw portion. By tightening the nut 54 to the lower end portion 50L (male screw portion) of the linear member 50, the nut 54 is locked to the lower surface of the upper connecting base 44U.

Further, the lower end portion 50L and the nut 54 of the linear member 50 are arranged in the moving space 49 of the beam-column joint member 40. As a result, the lower end portion 50L and the nut 54 of the linear member 50 can be moved to the opposite side (lower side) of the upper wooden pillar 14 with respect to the upper connecting base 44U.

Next, the operation of this embodiment will be described.

As shown in FIG. 1, according to the wooden column-beam joint structure 10 according to the present embodiment, a pair of column-beam joint members 40 are arranged above and below the wooden column 14. The pair of beam-column joint members 40 are connected by a linear member 50 that penetrates the wooden columns 14 in the timber axial direction. Further, beams 16 are joined to the pair of column-beam joint members 40, respectively.

As a result, in the event of an earthquake, for example, as shown in FIG. 4, the tensile force S is transmitted from the upper beam 16 to the upper end portion 50U of the linear member 50 via the column-beam joint member 40 and the nut 52. Similarly, a tensile force (not shown) is transmitted from the lower beam 16 to the lower end portion 50L of the linear member 50 via the column-beam joint member 40 and the nut 54. When the linear member 50 resists the tensile force S, the tensile force is transmitted between the wooden column 14 and the beam 16.

As described above, in the present embodiment, the wooden column 14 and the beam 16 can be joined so that the tensile force S can be transmitted. Therefore, the seismic performance of the frame 12 is improved.

Further, the frame 12 is provided with a seismic wall 20. Therefore, the frame 12 of the present embodiment has higher rigidity than the frame without seismic members such as the seismic wall 20, and the seismic force is easily concentrated. Further, when the steel beam 16 is directly joined (rigidly joined) to the wooden column 14, the structure of the joint portion (joint portion) may be complicated. The wooden column-beam joint structure 10 according to the present embodiment is particularly effective for such a frame 12, and by applying the wooden column-beam joint structure 10 to the frame 12, the joint portion between the wooden column 14 and the beam 16 ( While simplifying the structure of the joint portion), the tensile force can be transmitted between the wooden columns 14 and the beams 16 to ensure the seismic performance of the frame 12.

Further, the pair of beam-column joint members 40 have a lower connecting base 44L and an upper connecting base 44U. The lower connecting base 44L is in contact with the upper end surface 14U of the wooden pillar 14 so as to be separable. Therefore, for example, when a tensile force S is transmitted from the upper beam 16 to the beam-column joint member 40 at the time of an earthquake, as shown in FIG. 4, the lower connecting base 44L is transferred from the upper end surface 14U of the wooden column 14 to the lower connecting base 44L. Separate. As a result, the tensile force S is suppressed from being transmitted from the lower connecting base 44L to the upper end portion of the wooden pillar 14. Therefore, damage to the upper end of the wooden pillar 14 is suppressed.

Similarly, the upper connecting base 44U is in contact with the lower end surface 14L of the wooden pillar 14 so as to be separable. As a result, it is suppressed that the tensile force is transmitted from the lower beam 16 to the lower end portion of the wooden pillar 14 via the upper connecting base 44U at the time of an earthquake. Therefore, damage to the lower end of the wooden pillar 14 is suppressed.

Further, the upper end portion 50U of the linear member 50 is penetrated through the mounting hole 46 of the lower connecting base 44L. A nut 52 is attached to the upper end portion 50U of the linear member 50. By locking the nut 52 to the upper surface of the lower connecting base 44L, the upper end portion 50U of the linear member 50 is connected to the lower connecting base 44L. As a result, at the time of an earthquake, the tensile force S is transmitted from the upper beam 16 to the upper end portion 50U of the linear member 50 via the lower connecting base 44L and the nut 52.

Similarly, the lower end portion 50L of the linear member 50 is penetrated through the mounting hole 48 of the upper connecting base 44U. A nut 54 is attached to the lower end portion 50L of the linear member 50. By locking the nut 54 to the lower surface of the upper connecting base 44U, the lower end 50L of the linear member 50 is connected to the upper connecting base 44U. As a result, in the event of an earthquake, a tensile force is transmitted from the lower beam 16 to the lower end portion 50L of the linear member 50 via the upper connecting base 44U and the nut 54.

As described above, in the present embodiment, the tensile force can be transmitted to the linear member 50 while suppressing the damage of the upper and lower ends of the wooden pillar 14. Therefore, the seismic performance of the wooden pillar 14 is improved.

Here, as shown in FIG. 5, the wooden pillar 14 may be compressed in the timber axial direction by a vertical load N or the like. When the linear member 50 follows the compressive deformation of the wooden pillar 14, the linear member 50 may be curved in the through hole 15 of the wooden pillar 14, and the wooden pillar 14 may be damaged from the inside.

On the other hand, in the present embodiment, the nut 54 attached to the lower end portion 50L of the linear member 50 is not joined to the lower connecting base 44L, but is locked to the lower surface of the lower connecting base 44L. There is. Further, the nut 54 is arranged in the moving space 49 of the column-beam joint member 40.

As a result, when the wooden pillar 14 is compressed and deformed in the lumber axis direction, the nut 54 moves to the opposite side of the upper connecting base 44U with respect to the upper connecting base 44U, and downward from the upper connecting base 44U, as indicated by the arrow T. Separate. As a result, the locked state between the upper connecting base 44U and the nut 54 is released. Therefore, the linear member 50 does not follow the compressive deformation of the wooden pillar 14. Therefore, since the bending of the linear member 50 is suppressed, damage to the wooden pillar 14 and the like is suppressed.

Further, in the present embodiment, the earthquake-resistant wall 20 is not joined to the pair of wooden columns 14. As a result, the seismic force is suppressed from being directly transmitted from the shear wall 20 to the pair of wooden columns 14. Therefore, damage to the pair of wooden pillars 14 is suppressed.

Further, in the present embodiment, openings 18 are formed between the pair of wooden pillars 14 and the earthquake-resistant wall 20. These openings 18 ensure daylighting and ventilation, and allow equipment to pass through the openings 18 through pipes, wiring, and the like.

Next, a modified example of the above embodiment will be described.

In the above embodiment, the steel seismic wall 20 is provided on the frame 12, but the above embodiment is not limited to this. For example, as shown in FIG. 6, the frame 12 may be provided with a brace 60.

Specifically, a pair of steel braces 60 are arranged on the structure surface of the frame 12. The pair of braces 60 are arranged in a V shape. Each brace 60 is connected to a central portion 16M of the lower beam 16 and an end portion 16E of the upper beam 16. The rigidity of the frame 12 is increased by the pair of braces 60. The joint portion of the beam 16 with the brace 60 is reinforced by the rib 62.

Further, the pair of braces 60 and the pair of wooden pillars 14 are cut off from each other. As a result, it is possible to prevent the seismic force from being directly transmitted from the pair of braces 60 to the pair of wooden pillars 14 during an earthquake. Therefore, damage to the pair of wooden columns 14 is suppressed.

Further, in the above embodiment, the edge between the pair of wooden pillars 14 and the earthquake-resistant wall 20 is cut, but it is also possible to join the earthquake-resistant wall 20 to the pair of wooden pillars 14. Further, the seismic member is not limited to steel, and may be made of reinforced concrete (reinforced concrete) or wooden (woody). Further, the seismic member may be provided on the frame 12 as needed, and may be omitted as appropriate.

Further, in the above embodiment, the joint main body 42 of the column-beam joint member 40 is formed in a cross shape in a plan view, but the configuration of the joint main body 42 is not limited to this. For example, as shown in FIG. 7, the joint body portion 72 may be formed in an H shape in a plan view. In this case, two moving spaces 74 are formed in the column-beam joint member 70. Further, the joint body portion 42 may be formed in a cylindrical shape, for example, in a plan view.

Further, in the above embodiment, the upper connecting base 44U and the lower connecting base 44L are not joined to the wooden pillar 14, but the upper connecting base 44U and the lower connecting base 44L may be joined to the wooden pillar 14.

Further, the column-beam joint member 40 may be provided with at least one of the upper connecting base 44U and the lower connecting base 44L. Further, the configurations of the upper connecting base 44U and the lower connecting base 44L can be changed as appropriate, and may be formed in a block shape, for example.

Further, in the above embodiment, nuts 52 and 54 as locking members are provided at both ends of the linear member 50, respectively, but the above embodiment is not limited to this. For example, a locking member may be provided at one end of the linear member 50, and the other end of the linear member 50 may be fixed to the beam-column joint member 40 by welding or the like. Also in this case, the transmission of the compressive force to the linear member 50 is suppressed. When the end of the linear member 50 is fixed to the beam-column joint member, the connecting base for locking the locking member can be omitted. It is also possible to fix both ends of the linear member 50 to the beam-column joint member.

Further, in the above embodiment, the locking members are nuts 52 and 54, but as the locking member, a clip or coupler that can be locked to the lower connecting base 44L or the like may be used.

Further, in the above embodiment, a plurality of linear members 50 are provided on the wooden pillar 14, but at least one linear member 50 can be provided on the wooden pillar 14. It is also possible to introduce pretension into the linear member 50.

Further, in the above embodiment, the beam 16 is made of steel, but the beam may be made of reinforced concrete, steel-framed reinforced concrete, wooden, or the like. Further, the horizontal member is not limited to the beam 16, and may be, for example, a slab (concrete slab).

Although one embodiment of the present invention has been described above, the present invention is not limited to such an embodiment, and one embodiment and various modifications may be used in combination as appropriate. Of course, it can be carried out in various modes as long as it does not deviate.

10 Wood column beam joint structure 14 Wood column 14L Lower end surface (end surface of wood column)
14U Top surface (end surface of wooden pillar)
16 Beam (horizontal member)
16A Flange part 40 Column beam joint member 44L Lower connection base (connection base)
44U upper connection base (connection base)
49 Moving space 50 Linear member 50L Lower end (end of linear member)
50U upper end (end of linear member)
52 Nut (locking member)
54 nut (locking member)
70 Column beam joint member 74 Moving space

Claims (3)

A wooden pillar with a through hole that penetrates in the direction of the lumber axis,
A pair of column-beam joint members that are arranged above and below the wooden columns and to which horizontal members are joined, respectively.
With the linear member connecting the pair of beam-column joint members in a state where the through hole is slidably penetrated,
Equipped with a,
The beam-column joint member has a connecting base through which an end portion of the linear member is penetrated.
At the end of the linear member, a locking member that is movably locked to the connecting base on the side opposite to the wooden pillar is provided.
Woody beam-to-column junction structure. The connecting base is separably contacted with the end face of the wooden pillar .
The wooden column-beam joint structure according to claim 1. The column-beam joint member has a moving space in which the locking member can move.
The wooden column-beam joint structure according to claim 2.

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